BINDING KINETICS OF FREE- AND TOTAL-PROSTATE SPECIFIC ANTIGEN USING FRACTAL ANALYSIS ATUL M. DOKE AND AJIT SADANA CHEMICAL ENGINEERING DEPARTMENT AND COMPOSITE STRUCTURES AND NANOENGINEERING RESEARCH GROUP UNIVERSITY OF MISSISSIPPI UNIVERSITY, MS MAESC CHRISTIAN BROTHERS UNIVERSITY, MEMPHIS MAY 11, 2005
FRACTAL ANALYSIS USED TO MODEL THE BINDING KINETICS OF FREE- AND TOTAL-PROSTATE SPECIFIC ANTIGEN (f-PSA AND t-PSA) BY BIOSENSORS.
INTRODUCTION LANDIS ET AL. (1999) INDICATE THAT SERUM PROSTATE-SPECIFIC ANTIGEN (PSA) IS A RELIABLE TUMOR MARKER IN THE EARLY DETECTION OF PROSTATE CANCER PANNEK ET AL. (1998) INDICATE THE RATIO OF FREE- TO TOTAL-PSA TO BE A GOOD METRIC OF DIAGNOSIS OF PROSTATE CANCER THE RATIO DECREASES AS THE DISEASE EMERGES
FRACTAL ANALYSIS IS USED TO RE-ANALYZE THE BINDING DATA OF DIFFERENT CONCENTRATIONS OF f-PSA AND t-PSA TO RESPECTIVE ANTIBODIES IMMOBILIZED ON A NITROCELLULOSE MEMBRANE SURFACE THE ANALYSIS PROVIDES VALUES OF THE BINDING RATE COEFFICIENT AND THE FRACTAL DIMENSION ON THE BIOSENSOR SURFACE
What are Fractals? SELF-SIMILAR OBJECTS THEY DON’T HAVE TO BE IDENTICAL SIMILAR SHAPE BUT DIFFERENT HEIGHT OR WIDTH FRACTALS REPRESENT: (1) SYSTEMS HAVING COMPLEX SHAPES (2) CHARACTERIZED BY NON-INTEGER DIMENSIONALITY
Fractal Theory
SINGLE-FRACTAL ANALYSIS BINDING RATE COEFFICIENT HAVLIN INDICATES THAT THE DIFFUSION OF A PARTICLE (ANALYTE [Ag]) FROM A HOMOGENEOUS SOLUTION TO A SOLID SURFACE (E.G., RECEPTOR [Ab] COATED SURFACE) ON WHICH IT REACTS TO FORM A PRODUCT IS GIVEN BY:
DUAL-FRACTAL ANALYSIS BINDING RATE COEFFICIENT IN THIS CASE, THE ANALYTE-RECEPTOR COMPLEX ON THE BIOSENSOR SURFACE IS GIVEN BY: t (3- D f1,bind ) / 2 = t p1 (t < t1) (Ab.Ag) ≈ t (3- D f2,bind )/2 = t p2 (t1 <t <t2) = t c t 1/2 (t > t c )
RESULTS FERNANDEZ-SANCHEZ ET AL. (2004) INDICATE THE USE OF A DISPOSABLE NON-COMPETITIVE IMMUNOSENSOR TO DETECT f-PSA AS WELL AS t-PSA STRIPS OF A NITROCELLULOSE MEMBRANE WERE USED WITH APPROPRIATE ANTIBODIES FOR f-PSA AND t-PSA
BINDING KINETICS FOR f-PSA A B C FIG:1
D E FIG:1
FIG 1A : BINDING OF 0 ng/mL OF FREE-PSA TO ANTI-FREE PSA COATED IMMUNOSTRIP SINGLE-FRACTAL ANALYSIS REQUIRED FOR BINDING FIG 1B,1C,1D & 1E : BINDING OF 1, 3, 10 AND 100 ng/mL OF FREE-PSA TO ANTI-FREE PSA COATED IMMUNOSTRIP DUAL-FRACTAL ANALYSIS REQUIRED FOR BINDING
TABLE I: Binding Rate Coefficients and Fractal Dimension Values for Free Prostate Specific Antigen (f-PSA) in Solution to the Antibody, anti-free PSA Coated on a Nitrocellulose Membrane on an Electrochemical Transducer in a Lateral Flow Immunoassay Format. Effect of Different f-PSA Concentrations (Fernandez-Sanchez et al., 2004a) Free PSA concentration ng/mL kk1k1 k2k2 DfDf D f1 D f ± na ± na 12.4 E-06± 0.7 E E-06± 1.0 E E-05± 0.2 E E-05± 0.5 E E-06± 0.3 E E-05± 0.3 E E-06± 0.3 E E-07± 1.5 E E-05± 0.1 E ± na na
k 2 = (6.7 E-05 ± 0.4 E-05) [f-PSA] ±
BINDING KINETICS FOR t-PSA A B C FIG:2
D E FIG:2
FIG 3A: BINDING OF 0 ng/mL OF TOTAL-PSA TO ANTI-TOTAL PSA COATED IMMUNOSTRIP DUAL-FRACTAL ANALYSIS REQUIRED FOR BINDING FIG 3B & 3C : BINDING OF 1 AND 3 ng/mL OF TOTAL-PSA TO ANTI-TOTAL PSA COATED IMMUNOSTRIP SINGLE-FRACTAL ANALYSIS REQUIRED FOR BINDING FIG 3D & 3E : BINDING OF 10 AND 100 ng/mL OF TOTAL-PSA TO ANTI-TOTAL PSA COATED IMMUNOSTRIP DUAL-FRACTAL ANALYSIS REQUIRED FOR BINDING
TABLE II: Binding Rate Coefficients and Fractal Dimension Values for Total Prostate Specific Antigen (t-PSA) in Solution to the Antibody, anti-total PSA Coated on a Nitrocellulose Membrane on an Electrochemical Transducer in a Lateral Flow Immunoassay Format. Effect of Different t-PSA Concentrations (Fernandez-Sanchez et al., 2004a) Total PSA concentration ng/mL kk1k1 k2k2 DfDf D f1 D f ± ± E-07 ±1.5 E ± ± E-5± 0.6 E-05 na na 39.5 E-05± 2.6 E-05 na na ± ± E-06 ±1 E na E-05 ±5.0 E ± E-08 ±1.0E-09 na ± na
RESULTS FERNANDEZ-SANCHEZ ET AL. (2004) DEVELOPED A SANDWICH TYPE IMMUNOASSAY TO DETECT f-PSA AND t-PSA THIS IMMUNOSENSOR USED AN IMPEDANCE MEASUREMENT OF A DEGRADATION PROCESS OCCURING ON A pH-SENSITIVE POLYMER COATED ELECTRODE IMMUNOSTRIPS CONTAINED NITROCELLULOSE MEMBRANES WITH ANTI-f-PSA OR ANTI-t-PSA ANTIBODIES
A B C FIG:4
D E FIG:4
FIG 4A: BINDING OF 0 ng/mL OF FREE-PSA TO ANTI-FREE PSA COATED IMMUNOSTRIP SINGLE-FRACTAL ANALYSIS REQUIRED FOR BINDING FIG 4B, 4C, 4D & 4E : BINDING OF 1, 2,10 AND 30 ng/mL OF FREE- PSA TO ANTI-FREE PSA COATED IMMUNOSTRIP DUAL-FRACTAL ANALYSIS REQUIRED FOR BINDING
TABLE III: Binding Rate Coefficients and Fractal Dimension Values for Free Prostate Specific Antigen (f-PSA) in Solution to the antibody, anti-free PSA coated on a Nitrocellulose Membrane on an Electrochemical Transducer in a Lateral Flow Immunoassay Format. Effect of Different f-PSA Concentrations (Fernandez-Sanchez et al., 2004a) Free PSA concentration ng/mL kk1k1 k2k2 DfDf D f1 D f ± na ± na ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ± ±
k 1 = ( ± ) [f-PSA] ± k 1 = ( ± ) D f ±
A B C D FIG:6
FIG 6A, 6B, 6C AND 6D : BINDING OF 0, 2, 10 AND 30 ng/mL OF TOTAL-PSA TO ANTI-TOTAL PSA COATED IMMUNOSTRIP DUAL-FRACTAL ANALYSIS REQUIRED FOR BINDING
TABLE IV: Binding Rate Coefficients and Fractal Dimension Values for Total Prostate Specific Antigen (t-PSA) in Solution to the Antibody, anti-total PSA Coated on a Nitrocellulose Membrane on an Electrochemical Transducer in a Lateral Flow Immunoassay Format. Effect of Different t-PSA Concentrations (Fernandez-Sanchez et al., 2004a) Total PSA concentration ng/mL kk1k1 k2k2 DfDf D f1 D f ± ± E-07 ±1.5 E ± ± E-05 ±0.6 E-05 na na ± ± E-06 ±1 E ± ± na E-05 ±5.0 E ± E-08 ±1.0E-09 na ± na
k 1 = ( ± )[t-PSA] ± k 2 = ( ± )[t-PSA] ± k 1 = ( ± 0.026)D f ±
CONCLUSIONS A FRACTAL ANALYSIS IS APPLIED TO BINDING KINETICS OF f-PSA AND t-PSA IN SOLUTION TO THE BIOSENSOR SURFACE. THE VALUES OF THE BINDING RATE COEFFICIENT, k LINKED WITH THE DEGREE OF HETEROGENEITY EXISTING ON THE BIOSENSOR SURFACE PROVIDES A COMPLETE PICTURE OF THE REACTION KINETICS ON THE BIOSENSOR CHIP SURFACE.
THE DUAL-FRACTAL ANALYSIS IS USED ONLY WHEN THE SINGLE-FRACTAL ANALYSIS DID NOT PROVIDE AN ADEQUATE FIT. IT IS SUGGESTED THAT THE ROUGHNESS ON THE BIOSENSOR SURFACE LEADS TO TURBULENCE WHICH ENHANCES MIXING AND DECREASES DIFFUSIONAL LIMITATIONS (MARTIN ET AL., 1991). THIS LEADS TO AN INCREASE IN THE BINDING RATE COEFFICIENT ON THE BIOSENSOR CHIP SURFACE.